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bl_info = {
	"name": "Node Arrange",
	"author": "JuhaW",
	"version": (0, 2, 2),
	"blender": (2, 80, 4),
	"location": "Node Editor > Properties > Trees",
	"description": "Node Tree Arrangement Tools",
	"warning": "",
    "wiki_url": "https://docs.blender.org/manual/en/dev/addons/"
                "node/node_arrange.html",
	"tracker_url": "https://github.com/JuhaW/NodeArrange/issues",
	"category": "Node"
}


import sys
import bpy
from collections import OrderedDict
from itertools import repeat
import pprint
import pdb
from bpy.types import Operator, Panel
from bpy.props import (
    IntProperty,
)
from copy import copy


#From Node Wrangler
def get_nodes_linked(context):
    tree = context.space_data.node_tree

    # Get nodes from currently edited tree.
    # If user is editing a group, space_data.node_tree is still the base level (outside group).
    # context.active_node is in the group though, so if space_data.node_tree.nodes.active is not
    # the same as context.active_node, the user is in a group.
    # Check recursively until we find the real active node_tree:
    if tree.nodes.active:
        while tree.nodes.active != context.active_node:
            tree = tree.nodes.active.node_tree

    return tree.nodes, tree.links

class NA_OT_AlignNodes(Operator):
    '''Align the selected nodes/Tidy loose nodes'''
    bl_idname = "node.na_align_nodes"
    bl_label = "Align Nodes"
    bl_options = {'REGISTER', 'UNDO'}
    margin: IntProperty(name='Margin', default=50, description='The amount of space between nodes')

    def execute(self, context):
        nodes, links = get_nodes_linked(context)
        margin = self.margin

        selection = []
        for node in nodes:
            if node.select and node.type != 'FRAME':
                selection.append(node)

        # If no nodes are selected, align all nodes
        active_loc = None
        if not selection:
            selection = nodes
        elif nodes.active in selection:
            active_loc = copy(nodes.active.location)  # make a copy, not a reference

        # Check if nodes should be laid out horizontally or vertically
        x_locs = [n.location.x + (n.dimensions.x / 2) for n in selection]  # use dimension to get center of node, not corner
        y_locs = [n.location.y - (n.dimensions.y / 2) for n in selection]
        x_range = max(x_locs) - min(x_locs)
        y_range = max(y_locs) - min(y_locs)
        mid_x = (max(x_locs) + min(x_locs)) / 2
        mid_y = (max(y_locs) + min(y_locs)) / 2
        horizontal = x_range > y_range

        # Sort selection by location of node mid-point
        if horizontal:
            selection = sorted(selection, key=lambda n: n.location.x + (n.dimensions.x / 2))
        else:
            selection = sorted(selection, key=lambda n: n.location.y - (n.dimensions.y / 2), reverse=True)

        # Alignment
        current_pos = 0
        for node in selection:
            current_margin = margin
            current_margin = current_margin * 0.5 if node.hide else current_margin  # use a smaller margin for hidden nodes

            if horizontal:
                node.location.x = current_pos
                current_pos += current_margin + node.dimensions.x
                node.location.y = mid_y + (node.dimensions.y / 2)
            else:
                node.location.y = current_pos
                current_pos -= (current_margin * 0.3) + node.dimensions.y  # use half-margin for vertical alignment
                node.location.x = mid_x - (node.dimensions.x / 2)

        # If active node is selected, center nodes around it
        if active_loc is not None:
            active_loc_diff = active_loc - nodes.active.location
            for node in selection:
                node.location += active_loc_diff
        else:  # Position nodes centered around where they used to be
            locs = ([n.location.x + (n.dimensions.x / 2) for n in selection]) if horizontal else ([n.location.y - (n.dimensions.y / 2) for n in selection])
            new_mid = (max(locs) + min(locs)) / 2
            for node in selection:
                if horizontal:
                    node.location.x += (mid_x - new_mid)
                else:
                    node.location.y += (mid_y - new_mid)

        return {'FINISHED'}

class values():
	average_y = 0
	x_last = 0
	margin_x = 100
	mat_name = ""
	margin_y = 20


class NA_PT_NodePanel(Panel):
	bl_label = "Node Arrange"
	bl_space_type = "NODE_EDITOR"
	bl_region_type = "UI"
	bl_category = "Arrange"

	def draw(self, context):
		if context.active_node is not None:
			layout = self.layout
			row = layout.row()
			col = layout.column
			row.operator('node.button')

			row = layout.row()
			row.prop(bpy.context.scene, 'nodemargin_x', text="Margin x")
			row = layout.row()
			row.prop(bpy.context.scene, 'nodemargin_y', text="Margin y")
			row = layout.row()
			row.prop(context.scene, 'node_center', text="Center nodes")

			row = layout.row()
			row.operator('node.na_align_nodes', text="Align to Selected")

			row = layout.row()
			node = context.space_data.node_tree.nodes.active
			if node and node.select:
				row.prop(node, 'location', text = "Node X", index = 0)
				row.prop(node, 'location', text = "Node Y", index = 1)
				row = layout.row()
				row.prop(node, 'width', text = "Node width")

			row = layout.row()
			row.operator('node.button_odd')

class NA_OT_NodeButton(Operator):

	'''Arrange Connected Nodes/Arrange All Nodes'''
	bl_idname = 'node.button'
	bl_label = 'Arrange All Nodes'

	def execute(self, context):
		nodemargin(self, context)
		bpy.context.space_data.node_tree.nodes.update()
		bpy.ops.node.view_all()

		return {'FINISHED'}

	# not sure this is doing what you expect.
	# blender.org/api/blender_python_api_current/bpy.types.Operator.html#invoke
	def invoke(self, context, value):
		values.mat_name = bpy.context.space_data.node_tree
		nodemargin(self, context)
		return {'FINISHED'}


class NA_OT_NodeButtonOdd(Operator):

	'Show the nodes for this material'
	bl_idname = 'node.button_odd'
	bl_label = 'Select Unlinked'

	def execute(self, context):
		values.mat_name = bpy.context.space_data.node_tree
		#mat = bpy.context.object.active_material
		nodes_iterate(context.space_data.node_tree, False)
		return {'FINISHED'}


class NA_OT_NodeButtonCenter(Operator):

	'Show the nodes for this material'
	bl_idname = 'node.button_center'
	bl_label = 'Center nodes (0,0)'

	def execute(self, context):
		values.mat_name = ""  # reset
		mat = bpy.context.object.active_material
		nodes_center(mat)
		return {'FINISHED'}


def nodemargin(self, context):

	values.margin_x = context.scene.nodemargin_x
	values.margin_y = context.scene.nodemargin_y

	ntree = context.space_data.node_tree

	#first arrange nodegroups
	n_groups = []
	for i in ntree.nodes:
		if i.type == 'GROUP':
			n_groups.append(i)
			
	while n_groups:
		j = n_groups.pop(0)
		nodes_iterate(j.node_tree)
		for i in j.node_tree.nodes:
			if i.type == 'GROUP':
				n_groups.append(i)
		
	nodes_iterate(ntree)

	# arrange nodes + this center nodes together
	if context.scene.node_center:
		nodes_center(ntree)


class NA_OT_ArrangeNodesOp(bpy.types.Operator):
	bl_idname = 'node.arrange_nodetree'
	bl_label = 'Nodes Private Op'

	mat_name : bpy.props.StringProperty()
	margin_x : bpy.props.IntProperty(default=120)
	margin_y : bpy.props.IntProperty(default=120)

	def nodemargin2(self, context):
		mat = None
		mat_found = bpy.data.materials.get(self.mat_name)
		if self.mat_name and mat_found:
			mat = mat_found
			#print(mat)

		if not mat:
			return
		else:
			values.mat_name = self.mat_name
			scn = context.scene
			scn.nodemargin_x = self.margin_x
			scn.nodemargin_y = self.margin_y
			nodes_iterate(mat)
			if scn.node_center:
				nodes_center(mat)

	def execute(self, context):
		self.nodemargin2(context)
		return {'FINISHED'}


def outputnode_search(ntree):	 # return node/None

	outputnodes = []
	for node in ntree.nodes:
		if not node.outputs:
			for input in node.inputs:
				if input.is_linked:
					outputnodes.append(node)
					break

	if not outputnodes:
		print("No output node found")
		return None
	return outputnodes


###############################################################
def nodes_iterate(ntree, arrange=True):

	nodeoutput = outputnode_search(ntree)
	if nodeoutput is None:
		#print ("nodeoutput is None")
		return None
	a = []
	a.append([])
	for i in nodeoutput:
		a[0].append(i)


	level = 0

	while a[level]:
		a.append([])

		for node in a[level]:
			inputlist = [i for i in node.inputs if i.is_linked]

			if inputlist:

				for input in inputlist:
					for nlinks in input.links:
						node1 = nlinks.from_node
						a[level + 1].append(node1)

			else:
				pass

		level += 1

	del a[level]
	level -= 1

	#remove duplicate nodes at the same level, first wins
	for x, nodes in enumerate(a):
		a[x] = list(OrderedDict(zip(a[x], repeat(None))))

	#remove duplicate nodes in all levels, last wins
	top = level
	for row1 in range(top, 1, -1):
		for col1 in a[row1]:
			for row2 in range(row1-1, 0, -1):
				for col2 in a[row2]:
					if col1 == col2:
						a[row2].remove(col2)
						break

	"""
	for x, i in enumerate(a):
		print (x)
		for j in i:
			print (j)
		#print()
	"""
	"""
	#add node frames to nodelist
	frames = []
	print ("Frames:")
	print ("level:", level)
	print ("a:",a)
	for row in range(level, 0, -1):

		for i, node in enumerate(a[row]):
			if node.parent:
				print ("Frame found:", node.parent, node)
				#if frame already added to the list ?
				frame = node.parent
				#remove node
				del a[row][i]
				if frame not in frames:
					frames.append(frame)
					#add frame to the same place than node was
					a[row].insert(i, frame)

	pprint.pprint(a)
	"""
	#return None
	########################################



	if not arrange:
		nodelist = [j for i in a for j in i]
		nodes_odd(ntree, nodelist=nodelist)
		return None

	########################################

	levelmax = level + 1
	level = 0
	values.x_last = 0

	while level < levelmax:

		values.average_y = 0
		nodes = [x for x in a[level]]
		#print ("level, nodes:", level, nodes)
		nodes_arrange(nodes, level)

		level = level + 1

	return None


###############################################################
def nodes_odd(ntree, nodelist):

	nodes = ntree.nodes
	for i in nodes:
		i.select = False

	a = [x for x in nodes if x not in nodelist]
	# print ("odd nodes:",a)
	for i in a:
		i.select = True


def nodes_arrange(nodelist, level):

	parents = []
	for node in nodelist:
		parents.append(node.parent)
		node.parent = None
		bpy.context.space_data.node_tree.nodes.update()


	#print ("nodes arrange def")
	# node x positions

	widthmax = max([x.dimensions.x for x in nodelist])
	xpos = values.x_last - (widthmax + values.margin_x) if level != 0 else 0
	#print ("nodelist, xpos", nodelist,xpos)
	values.x_last = xpos

	# node y positions
	x = 0
	y = 0

	for node in nodelist:

		if node.hide:
			hidey = (node.dimensions.y / 2) - 8
			y = y - hidey
		else:
			hidey = 0

		node.location.y = y
		y = y - values.margin_y - node.dimensions.y + hidey

		node.location.x = xpos #if node.type != "FRAME" else xpos + 1200

	y = y + values.margin_y

	center = (0 + y) / 2
	values.average_y = center - values.average_y

	#for node in nodelist:

		#node.location.y -= values.average_y

	for i, node in enumerate(nodelist):
		node.parent =  parents[i]

def nodetree_get(mat):

	return mat.node_tree.nodes


def nodes_center(ntree):

	bboxminx = []
	bboxmaxx = []
	bboxmaxy = []
	bboxminy = []

	for node in ntree.nodes:
		if not node.parent:
			bboxminx.append(node.location.x)
			bboxmaxx.append(node.location.x + node.dimensions.x)
			bboxmaxy.append(node.location.y)
			bboxminy.append(node.location.y - node.dimensions.y)

	# print ("bboxminy:",bboxminy)
	bboxminx = min(bboxminx)
	bboxmaxx = max(bboxmaxx)
	bboxminy = min(bboxminy)
	bboxmaxy = max(bboxmaxy)
	center_x = (bboxminx + bboxmaxx) / 2
	center_y = (bboxminy + bboxmaxy) / 2
	'''
	print ("minx:",bboxminx)
	print ("maxx:",bboxmaxx)
	print ("miny:",bboxminy)
	print ("maxy:",bboxmaxy)

	print ("bboxes:", bboxminx, bboxmaxx, bboxmaxy, bboxminy)
	print ("center x:",center_x)
	print ("center y:",center_y)
	'''

	x = 0
	y = 0

	for node in ntree.nodes:

		if not node.parent:
			node.location.x -= center_x
			node.location.y += -center_y

classes = [
	NA_PT_NodePanel,
	NA_OT_NodeButton,
	NA_OT_NodeButtonOdd,
	NA_OT_NodeButtonCenter,
	NA_OT_ArrangeNodesOp,
    NA_OT_AlignNodes
]

def register():
	for c in classes:
		bpy.utils.register_class(c)

	bpy.types.Scene.nodemargin_x = bpy.props.IntProperty(default=100, update=nodemargin)
	bpy.types.Scene.nodemargin_y = bpy.props.IntProperty(default=20, update=nodemargin)
	bpy.types.Scene.node_center = bpy.props.BoolProperty(default=True, update=nodemargin)



def unregister():
	for c in classes:
		bpy.utils.unregister_class(c)

	del bpy.types.Scene.nodemargin_x
	del bpy.types.Scene.nodemargin_y
	del bpy.types.Scene.node_center

if __name__ == "__main__":
	register()
